Biochemical Characterization on Muscle Tissue of a Novel Biallelic Mutation in an Infant with Progressive Encephalopathy

Overview

Journal JIMD Rep

Publisher Wiley

Date 2024 Jan 8

PMID 38186851

Authors

Federica Silvia Ricci

Serena Stanga

Mariarosa Mezzanotte

Cristina Marinaccio

Rossella DAlessandro

Alessandra Soma

Stefano Sottemano

Alessandra Conio

Giovanni Morana

Marco Spada

Marina Boido

Tiziana E Mongini

Affiliations

Soon will be listed here.

Abstract

The gene encodes the mitochondrial protein aconitate hydratase, which is responsible for catalyzing the interconversion of citrate into isocitrate in the tricarboxylic acid (TCA) cycle. Mitochondrial aconitase is expressed ubiquitously, and deficiencies in TCA-cycle enzymes have been reported to cause various neurodegenerative diseases due to disruption of cellular energy metabolism and development of oxidative stress. We investigated a severe early infantile-onset neurometabolic syndrome due to a homozygous novel variant in exon 13 of the gene. The in vitro pathogenicity of this variant of unknown significance was demonstrated by the loss of both protein expression and its enzymatic activity on muscle tissue sample taken from the patient. The patient presented with progressive encephalopathy soon after birth, characterized by hypotonia, progressive severe muscle atrophy, and respiratory failure. Serial brain magnetic resonance imaging showed progressive abnormalities compatible with a metabolic disorder, possibly mitochondrial. Muscle biopsy disclosed moderate myopathic alterations and features consistent with a mitochondriopathy albeit nonspecific. The course was characterized by progressive worsening of the clinical and neurological picture, and the patient died at 5 months of age. This study provides the first report on the validation in muscle from human subjects regarding in vitro analysis for mitochondrial aconitase activity. To our knowledge, no prior reports have demonstrated a correlation of phenotypic and diagnostic characteristics with in vitro muscle enzymatic activity of mitochondrial aconitase in humans. In conclusion, this case further expands the genetic spectrum of variants and defines a complex case of severe neonatal neurometabolic disorder.

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Biochemical characterization on muscle tissue of a novel biallelic mutation in an infant with progressive encephalopathy.

Ricci F, Stanga S, Mezzanotte M, Marinaccio C, DAlessandro R, Soma A JIMD Rep. 2024; 65(1):3-9.

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